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Reconfigurable water-substrate based antennas with temperature controlAhmed Toaha Mobashsher and Amin Abbosh
Citation: Appl. Phys. Lett. 110, 253503 (2017); doi: 10.1063/1.4986788View online: http://dx.doi.org/10.1063/1.4986788View Table of Contents: http://aip.scitation.org/toc/apl/110/25Published by the American Institute of Physics
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Reconfigurable water-substrate based antennas with temperature control
Ahmed Toaha Mobashshera) and Amin AbboshSchool of ITEE, The University of Queensland, St. Lucia, QLD 4072, Australia
(Received 17 March 2017; accepted 6 June 2017; published online 19 June 2017)
We report an unexplored reconfigurable antenna development technique utilizing the concept of
temperature variable electromagnetic properties of water. By applying this physical phenomena,
we present highly efficient water-substrate based antennas whose operating frequencies can be
continuously tuned. While taking the advantage of cost-effectiveness of liquid water, this dynamic
tuning technique also alleviates the roadblocks to widespread use of reconfigurable liquid-based
antennas for VHF and UHF bands. The dynamic reconfigurability is controlled merely via external
thermal stimulus and does not require any physical change of the resonating structure. We demon-
strate dynamic control of omnidirectional and directional antennas covering more than 14 and
12% fractional bandwidths accordingly, with more than 85% radiation efficiency. Our temperature
control approach paves the intriguing way of exploring dynamic reconfigurability of water-based
compact electromagnetic devices for non-static, in-motion and low-cost real-world applications.
Published by AIP Publishing. [http://dx.doi.org/10.1063/1.4986788]
In recent years, there has been a growing interest in
using liquidity of metals and substrates in realizing recon-
figurable devices from the microwave to the optical parts
of the spectrum. Liquid metals [Eutectic gallium indium
(EGaIn),1,2 Mercury,3,4 Galinstan,5 etc.] attain frequency
reconfigurable operation by using pressure6,7 or electrical
potential8,9 variations. Substrates, like liquid crystals,10
mechanically11 or thermally12 controllable dielectric
particles, nano-patterned meta-surfaces,13 meta-liquid
crystals,14 and water15 are also popularly used for recon-
figurable electromagnetic applications. Considering the
access, expense, and complexity of operation, water is
more attractive when compared to other liquids. However,
in most of the reported reconfigurable antennas,15 water
acts as a dielectric resonator and they require large volume
of water, which is inversely proportional to the operating
frequency. As a result, the antennas become bulky, heavy
weight, and unsuitable for applications that require
antenna repositioning, like finding the direction of signal
arrival or radar applications. By controlling liquid flow,
water-air interface16,17 is recently used to attain tunable
properties. However, the physical structures of these water
based devices are needed to be varied for reconfigurable
operation, and this variation requires complex mechanical
structures. Nonetheless, these methods are susceptible to
vibration and not suitable for non-static and in-motion/
vehicular applications.
In this work, we present a concept of frequency reconfigu-
ration of liquid water-substrate antennas by using temperature
as the controlling operator. The technique utilizes the tempera-
ture dependent dielectric properties of pure water. Tuning is
achieved by designing the antenna to operate at different fre-
quencies in different temperatures. While this reconfiguring
technique takes advantage of high dielectric loading of water-
based antennas, it has the following three main advantages
over typical physically reconfigurable water-substrate antenna
technique15 in terms of real-world applicability: (i) the pro-
posed technique does not require any physical changes to the
antenna for reconfiguration, (ii) antennas are light weight, and
(iii) as the antenna structure is fixed, the designed antennas are
not motion sensitive. Thus, this technique is suitable for vehic-
ular/maritime applications and is most effective and efficient
in VHF and UHF bands.
Water demonstrates dispersive electromagnetic proper-
ties in different frequencies. Moreover, those properties sig-
nificantly vary at different temperatures.18 Although recently
performance of temperature variable water based device is
reported,19 the applicability is only limited for electromag-
netic absorption. However, in order to develop a frequency
reconfigurable water-substrate based antenna on temperature
control approach, the choice of frequencies is vital for radia-
tion of electromagnetic waves with high efficiency. It is
noted [Figs. 1(a) and 1(b)] that at low frequencies, 0 �Ctemperature water demonstrates highest permittivity er(f,T)and loss-tangent tan d(f,T) values. However, there is a reso-nance in er(f,T) plot, beyond which a steep downward trendin permittivity values is observed. The resonance shifts to
FIG. 1. Temperature dependence of the permittivity and loss tangent of water
from 0.01–30 GHz: actual values of (a) relative permittivity [er(f,T)] and (b)loss tangent [tan d(f,T)¼ei(f,T)/er(f,T)] of water from 0 to 100 �C in 25 �Cinterval versus frequency, attained from the formulated equations for the com-
plex relative permittivity, e*(f,T) [¼er(f,T)� j ei(f,T)] of water.18 The second-ary axis represents the relative fractional variation of permittivity and loss
tangent of water as the temperature changes from 0 �C to higher over differentfrequencies.a)Electronic mail: [email protected]
0003-6951/2017/110(25)/253503/5/$30.00 Published by AIP Publishing.110, 253503-1
APPLIED PHYSICS LETTERS 110, 253503 (2017)
http://dx.doi.org/10.1063/1.4986788http://dx.doi.org/10.1063/1.4986788mailto:[email protected]://crossmark.crossref.org/dialog/?doi=10.1063/1.4986788&domain=pdf&date_stamp=2017-06-19
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higher frequencies with the increase of temperature. In low
frequencies, the permittivity changes monotonously with the
increase of temperature from 0 �C and variation reaches ashigh as 32 (relatively around 36%) at 100 �C. On the otherhand, the loss tangent varies non-monotonously. The rates of
loss tangent enhancement for temperature increment are
higher in the low temperature region and it becomes highest
at 100 �C with relative variation of around 87% from thoseof 0 �C water.
Previously, vanadium dioxide (VO2) is applied to
develop thermally control hybrid-metamaterial.17 But due to
its high tan d(f,T) values, VO2 suffers from low transmissioncapability. Owing to the facts that (i) the antenna loading
and miniaturization mostly depends on the effective permit-
tivity, and (ii) loss tangent defines the material loss of the
antenna,20 both dielectric properties are critical for efficient
antenna operation. Thus, high relative variations of permit-
tivity provide the antenna an extended tunability and high
loss tangent values result in low efficiencies. Following this
criteria, it is noted that at high microwave frequencies
(>10 GHz), the relative permittivity change can reach ashigh as 250% for 100 �C temperature variation, while the rel-ative variation in loss tangent slightly changes; the designed
antennas will provide the highest tunability. However, the
antennas designed in this high microwave frequency region
will also have very low efficiency due to the high tan d(f,T)values. Although the efficiency can be improved by using
partial loading technique,15 it is unable to take full advantage
of dielectric loading and thus reduces the tunable region.
Hence, considering the actual values of loss tangent and rela-
tive changes of permittivity, it can be concluded that the
temperature dependent reconfigurability by using water as a
substrate is more appropriate for VHF and UHF bands.
In order to demonstrate omnidirectional radiation from a
reconfigurable source, a water loaded dipole antenna having
two thin copper strips is designed utilizing 3D electromag-
netic simulation software CST Microwave Studio.21 While
other different types of omnidirectional antenna can be
designed following the water loading technique, dipole type
is chosen for simplicity and well-defined characteristics for
comparison. The antenna [Figs. 2(a) and 2(b)] consists of
two strips with total length of la and strip width of ta, whichare excited at the centre with a feeding gap of S. The metallicstrips are positioned at the center of the water substrate,
which has width, length, and height of tw, lw; and hw, respec-tively. In order to emulate the realistic scenario, frequency
dispersive complex relative permittivity [e*(f,T)] is definedduring the simulation process.21 The frequency dispersive
effective permittivity due to the water loading of different
temperatures on the dipole can be calculated using the fol-
lowing formula,
eeff f ; Tð Þ � 1þ er f ; Tð Þ � 1ð ÞK1 þ K2ð Þ
2 K3 þ K4ð Þ;(1)
where Ki¼ K kið ÞK0 kið Þ, i¼1 to 3 and k1¼sinh
p la�Sð Þ2h½ �
sinhp laþSð Þ
2h½ �, k2¼
tanh pS2 twþtað Þ½ �
sinhp Sþ2lað Þ2 twþtað Þ
� �,
k3¼ la�SlaþS, k4¼S
Sþ2la. Equation (1) is calculated by transform-
ing the total capacitance caused by the driven copper strips
into equivalent parallel-plate capacitance using conformal
mapping technique.22
Different parameters of the loaded dipole are optimized to
attain wide tuning bandwidth and high efficiency. The optimi-
zation process includes a target function in terms of maximum
bandwidth and efficiency, while the physical dimensions, as
indicated in Fig. 2(b), of the water-loaded antenna are opti-
mized to resonate in dipole mode. The antenna is prototyped
[Fig. 2(c)] and measured for validation using a vector network
analyzer (Rohde & Schwarz ZVA24). The water is contained
in a transparent Plexiglas box with wall thickness of 1 mm.
Owing to the thin layer of Plexiglass and its low permittivity
(3.2), the box has negligible effect on the performance of
the antenna. Nonetheless, the effect is considered in simula-
tions and measurements. The reflection coefficient versus fre-
quency graphs [Figs. 2(d) and 2(e)] show that the simulated
water-based antenna demonstrates a frequency reconfigurable
operation of around 14% bandwidth covering from 0.195 to
0.224 GHz frequency band using 100 �C temperature control.Because of the highest permittivity values at 0 �C, the antennacovers the lower end of the tunable bandwidth and the operat-
ing frequencies gradually moves to higher values with the
increase of temperature and the reduction of permittivity.
The prototyped antenna operates from 0.192 to 0.223 GHz,
which is equivalent to 14.9% fractional bandwidth. The radia-
tion efficiency of the antenna is also calculated from the 3D
simulations of CST environment by taking both conductor and
substrate material losses into account. Figure 2(f) shows that
the antenna operates with more than 88% radiation efficiency
over the reconfigurable region from 0 to 100 �C. Moreover, thetotal efficiency of the antenna, which considers radiation effi-
ciency with the mismatch loss,20 demonstrates more than 87%
efficiency over the whole tunable range. The far-field radiation
characteristics of the antenna is also measured in the standard
anechoic chamber facility of the University of Queensland.
The prototyped antenna attains highest gain of 1.4 dBi at
100 �C, while the gain is 0.6 dBi when operating at 0 �Ctemperature. The efficiency and gain increase systematically,
however their variations can be related to the relative change
FIG. 2. (a) Perspective view of the designed antenna indicating different parts of
it. (b) Top and side views illustrating the geometrical schematics of the water-
substrate based antenna. (c) Photograph of the prototyped antenna. The (d) simu-
lated and (e) measured reflection coefficient versus frequency performance of the
optimized antenna. (f) The calculated radiation and total efficiencies of the recon-
figurable antenna along with the simulated and measured gain values at resonat-
ing frequencies while operating in different temperatures.
253503-2 A. T. Mobashsher and A. Abbosh Appl. Phys. Lett. 110, 253503 (2017)
-
of the loss tangent, which is seen to change at slightly reduced
rate in the higher temperatures when compared to the lower
temperature end. Another reason for such reduced gain perfor-
mance compared to the gain of a typical half-wave dipole in
free space can be attributed to the reduction of equivalent elec-
trical length20 of the antenna due to the water-substrate load-
ing. The size of the proposed antenna is around half of a
typical half-wave dipole in free space. Since size of the
antenna is one of the main limiting factors in VHF and UHF
bands, such low-cost water-substrate loading can be used as an
alternate to the typical varactor diode mounting, which results
in low radiation efficiency and constrains the power handling
capability of the antenna.23 Nonetheless, the radiation patterns
of the proposed antenna at the resonating frequencies for dif-
ferent temperatures are found to be of a typical dipole mode.
No pattern deformation is noted for the loading of high dielec-
tric water substrate.
From Fig. 3(a), it can be seen that the height (hw) ofwater substrate has a dramatic effect on the resonance fre-
quency and tunable band of the reconfigurable antenna. With
the increase of vertical height of the substrate, the effective
permittivity rapidly increases, which consequently reduces
the resonating frequencies of the antenna. However, it is
noted that as hw gradually increases, the bandwidth (BW) ofthe antenna at individual temperatures decreases, resulting a
gradual increase of quality factor (Q), following the rela-tion,24 Q � 2=BW. The Q factor of the antenna is defined24as the quotient between the stored and dissipated powers in
the reactive field by
Q ¼ 4pf max We;Wmf gPd
; (2)
where We and Wm are stored electric and magnetic powers,Pd is the dissipated power and f is the frequency under
consideration. Noting the resonating frequencies decrease
with the increment of hw, an explanation can be drawn forsuch increment of Q. Owing to the fact that the effectivepermittivity values increase [eeff f ; Tð Þ from Eq. (1)] withincreasing hw, the stored energies rapidly develop. Theincrease of stored energies is also evident from the increase
of capacitive portion of the antenna impedance. Equation (2)
suggests that as a result, the Q factor increases and conse-quently results in a reduction of the operating bandwidth at a
specific temperature. Thus, the antenna becomes more sensi-
tive to the parametric variations. Because of this increased
sensitivity, the tunable bandwidth for temperature change
between 0 and 100 �C remains around 13%, even though thegap between highest (at 100 �C) and lowest (at 0 �C) valuesof the resonances gradually extends. The lower end [Fig.
3(b)] of the radiation efficiency range is defined by tan d(f,T)of 0 �C water. As the total amount of lossy water increaseswith increasing hw, the radiation efficiency of the antennadecreases. However, the rate of radiation efficiency reduc-
tion at 100 �C is much slower when compared to that of 0 �Cwater-substrate antenna because of the much lower material
losses in high temperatures. Similar conclusions of radiation
efficiency can be drawn from Fig. 3(c) for the rate of peak
gain (G) reduction.24 However, when compared to the effectof hw, the substrate loading effect of tw is much less. Thus,in typical optimization process, we suggest emphasizing on
hw over tw to accomplish compact reconfigurable antennasolution.
The bounds of radiation efficiencies of the water-
substrate based antennas in different operating frequencies
directly depend on the amount of substrate loading. As pre-
sented in the simulation derived results of Figs. 3(d)–3(f),
the pattern of radiation efficiency variation of the antenna at
a particular frequency is the same for both height (hw) orthickness (tw) variation. This indicates that the volume of thewater substrate is the dominant factor along with the
frequency-dispersive loss tangent of water in determining
the efficiency. As noted from the radiation efficiency limits
of Figs. 3(d)–3(f), while the proposed antenna is most effi-
cient in VHF owing to low dielectric losses of water, high
efficiencies can still be attained in high UHF (e.g., 1.5 GHz)
with moderate water loading. However, the magnitude of
compactness, which is proportional to substrate loading,
reduces in this case. High temperature water is more suitable
for efficient antenna reconfigurability. At 100 �C, water-based dipole antennas can provide more than 85% radiation
efficiencies in high UHF region.
Temperature controllability of water-substrate based
antenna can also be employed to develop directional recon-
figurable antennas. To that end, a quasi-Yagi type25 direc-
tional antenna is designed [Fig. 4(a)] by utilizing the
previously described omnidirectional dipole and a reflector.
The temperatures of both driven dipole and reflector are var-
ied simultaneously from 0 to 100 �C. The extracted 3D fullwave electromagnetic simulation results [Fig. 4(b)] show
that the tunable antenna operates from 0.2 to 0.226 GHz,
which is equal to 12.2% fractional bandwidth with the center
frequency of 0.213 GHz. Measured impedance matching
results are found to closely match the simulated perfor-
mance. More importantly, the antenna demonstrates stable
FIG. 3. Performance analyses of the temperature controlled reconfigurable
antenna in terms of (a) operating frequency, (b) efficiency, and (c) gain,
while the height of the water loading is varied with temperature change from
0 to 100 �C. The optimum parameters of the prototyped antenna are (inmm): ta¼5, tw¼40, la¼380, lw¼400, ha¼0.2, hw¼20, and S¼3. Radiationefficiency limits of a water-loaded dipole antenna as a function of normal-
ized water electrical thickness (tw/k0 or hw/k0) at (d) 0.2, (e) 0.8, and (f)1.5 GHz. The lower and upper ends of the shaded region denote efficiencies
at 0 and 100 �C, respectively.
253503-3 A. T. Mobashsher and A. Abbosh Appl. Phys. Lett. 110, 253503 (2017)
-
directional radiation patterns [Figs. 4(c) and 4(d)] over the
whole bandwidth while varying the temperature. At the tun-
able ends of 0 and 100 �C, the antenna, respectively attainsaround 5.3 and 6 dBi gain along desired þZ direction witharound 88% and 86% radiation efficiency accordingly. No
side lobe is observed, which indicates enhanced polarization
purity from the directional antenna.
Operation of the directional antenna crucially depends on
the distance of the director (dr). The radiation efficiency ofthe antenna [Fig. 4(e)] at 100 �C only slightly varies with thechange of dr due to low loss tangent values. Since this temper-ature state is at high end of the reconfigurable band, which
ensures resonating at smaller wavelengths, the antenna attains
peak gain values rapidly with a much smaller dr value, whencompared to the state of 0 �C, which operates at longer wave-lengths. For the higher mutual coupling for longer wave-
lengths as well as the higher lossy substrate loading at 0 �C,the director needs to be kept at around 0.13 k0 away from thedriven element in order to get high radiation efficiencies. It is
noted that extending dr beyond this distance does not add anyadditional performance advantage. The far-field gain perfor-
mance of the antenna is verified through anechoic chamber
measurements [Fig. 4(f)]. The optimum geometries of the
antenna are (in mm): trw¼40, lrw¼420, hrw¼20, tr¼10, anddr¼200.
While thermal tuning offers dynamic control of direc-
tional and omnidirectional antennas, its response time is
inherently limited by the cooling timescale of water.
Designing an adequate heating and cooling system can
reduce the response, which can be calculated from the rate of
heat transfer, Q by using the basic thermodynamics equation,
Q ¼ MCDT, where the total mass of water, M ¼ 0:32 and0:65 kg accordingly for the omnidirectional and directionalantennas, heat capacity of water, C ¼ 4:2 kJ= kg Kð Þ, and DTis the required temperature increment. In order to put this
equation into context, around 6.1 and 12.4 s are required to
increase the temperatures of the designed omnidirectional
and directional antennas, respectively, by 10 �C using a typi-cal 2.2 kW low-cost water-heater with small form factor.
During the prototyped antenna measurement process, we uti-
lized a standard water-heater. An infra-red thermometer
(SainSonic DT8380) was used to ensure the operating tem-
perature. A practical, low-cost way of implementing continu-
ous temperature control of water is by mixing hot and cold
water from different reservoirs. In this case, the inlet valve
needs to be programmed to flow Vh and Vc volume of hotand cold water: Vh ¼ VrDTh=DT and Vc ¼ VrDTc=DT, whereVr is the required volume of water, DTh and DTc are the tem-perature differences of the required temperature to those of
hot and cold water, accordingly and DT is the temperaturedifference between hot and cold water. A thermostat can be
utilized to maintain the feedback loop.
In conclusion, we have demonstrated the idea and pros-
pects of reconfigurable water-substrate based antenna using
temperature control technique. The antennas overcome the
limitations of previously described physically reconfigurable
FIG. 4. (a) Schematic diagram of the
water-loaded temperature controlled
reconfigurable quasi-Yagi antenna. (b)
Simulated and measured impedance
matching characteristics of the direc-
tional antenna at 0 and 100 �C. Theshaded region indicates the tunable
region. The simulated 3D radiation
patterns with respect to the antenna
when operating at (c) 0 and (d) 100 �Ctemperature. (e) Radiation and total
efficiency, and (f) simulated and mea-
sured gain performance of the direc-
tional antenna with different director
(dr) distances.
253503-4 A. T. Mobashsher and A. Abbosh Appl. Phys. Lett. 110, 253503 (2017)
-
water-based antennas15 and can be thus used as an alterna-
tive to the typical varactor diode based technique.23 Two
proof of concept antennas are designed. The performance of
the antennas is explained in detail and suggestions for opti-
mum tunable operation are also addressed. Despite the com-
pact and light-weight (traditional water based antennas
utilizes 6–10 l of water for reconfigurability,15 while the pro-
posed antenna use 0.32 and 0.65 l of water for omnidirec-
tional and directional operation, respectively) construction of
the proposed omnidirectional and directional antennas, the
radiation performance, including efficiencies, gain, and radi-
ation patterns, are comparable to previously described bulky
water-based antennas.15 Furthermore, compared to the fre-
quency reconfiguration using the height control, the pro-
posed tuning technique is less susceptible of vibration owing
to its confined physical structure. This technique of reconfi-
gurability is a strong candidate for non-static, low-cost solu-
tions in VHF and UHF bands.
This work was supported by the University of
Queensland Early Career Researcher Grant (Grant No.
UQECR1719917).
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